植物钙感受器及其介导的逆境信号途径

钙信号是植物生长发育和逆境响应的重要调控因子, 是植物生理与逆境生物学研究领域中的热点之一。当植物细胞受到外界逆境刺激时, 其胞内会产生具有时空特异性的Ca2+信号变化, 这种变化首先被胞内钙感受器所感知并解码, 再由钙感受器互作蛋白将信号传递到下游, 从而激活下游早期响应基因的表达或相关离子通道的活性, 最终产生特异性逆境响应。植物细胞通过感知胞内钙信号的变化如何识别来自外界不同性质或不同强度的刺激, 是近几年植物生物学家所关注的科学问题。文章主要总结了近几年在植物钙感受器研究领域中的最新进展, 包括钙依赖蛋白激酶(CDPKs)、钙调素(CaMs)、类钙调素蛋白(CMLs)、类钙调磷酸酶B蛋白(CBLs)及其互作蛋白激酶(CIPKs)等的结构、功能及其介导的逆境信号途径, 并提供新的见解和展望。     

植物逆境miRNA研究进展

包括生物和非生物在内的多种逆境胁迫是植物正常生长和作物产量提高的重要限制性因素。植物在长期的进化过程中, 通过诱导表达某些抵御或防卫途径的关键基因来实现对胁迫的响应。研究表明, 逆境胁迫不仅会诱导植物蛋白质编码基因的表达, 也会诱导一些非蛋白质编码基因的表达, 这类非蛋白质编码基因的表达产物在植物的生长、发育和应对逆境胁迫等过程中起到重要的调控作用。miRNA(小分子RNA)就是这类非蛋白质编码基因产物中的重要类群, 研究发现, 多种逆境均会诱导miRNA的产生, 其作用是通过引导目的基因mRNA的降解和阻止翻译过程来调控靶基因, 最终通过形态或生理上的变化达到对逆境的适应。文章主要对植物逆境胁迫下miRNA的研究, 特别是逆境胁迫诱导miRNA的产生、靶基因调控以及miRNA在植物适应逆境胁迫过程中的作用进行了综述, 同时, 文章还对在逆境胁迫下植物miRNA的研究方法进行了初步的探讨。     

磷脂酸的诱导和降解在植物逆境响应中的作用

磷脂酸(phosphatidic acid,PA)是植物中重要的脂质信号分子,被称为"脂质第二信使",参与多种逆境胁迫相关的信号传导途径.植物体内的PA可通过直接的磷脂酶D途径和间接的磷脂酶C途径产生.当植物受到胁迫刺激后,细胞内的PA含量会在几分钟内升高,在胁迫消失后经磷酸化作用形成甘油二酯焦磷酸降解,恢复到正常水平...     

植物应答非生物胁迫的蛋白质组学研究进展

逆境对植物的生长发育产生不利影响,植物在长期适应环境中演化出了相应的机制。蛋白质是基因表达的最终产物,是细胞生命活动的基础,在逆境条件下,许多与逆境相关的蛋白质表达量发生变化。蛋白质组学技术的发展为鉴定和研究逆境响应相关蛋白提供了手段,为阐述逆境应答分子机理提供了重要的依据。本综述根据近年来采用蛋白质组学研究植物应答非生物胁迫(干旱,高盐和低温)的结果,总结并讨论了不同逆境下蛋白表达的组织特异性特点,旨在为理解植物的逆境胁迫响应机制提供更多信息。     

钙信使在植物适应非生物逆境中的作用

综述了非生物逆境胁迫下植物体内钙信号的产生,特点及植物在适应逆境中钙信使系统的可能作用。     

逆境胁迫下ABA与钙信号转导途径之间的相互调控机制

Ca2+信号是植物应答各种逆境胁迫响应的一个重要组分,它在植物抗病、抗虫及适应非生物胁迫反应中起着重要的作用.Caz+信号作为第二信使在激素信号转导尤其是ABA信号转导过程中发挥着重要作用.研究表明,当植物受到如干旱、低温、盐害等环境胁迫时,细胞迅速积累ABA,胞内钙离子浓度瞬间升高,然后钙离子浓度呈现忽高忽低的震荡现象.在植物细胞中发现Caz+/CDPK、Caz+/CaM和Caz+/CBL三类钙信号系统,它们与逆境胁迫信号转导密切相关.本文通过综述植物在逆境条件下,ABA与钙信号的产生、转导及产生适应性和抗性等方面,介绍了ABA与钙信号之间的相互调节机制.     

植物细胞外信号分子eATP研究进展

细胞外ATP(extracellular ATP, eATP)是目前公认的细胞外信号分子, 参与调控多种环境刺激下植物的生长、发育和防御反应。在植物细胞信号转导过程中, eATP具有双重功能, 其作用主要取决于细胞外基质中eATP的浓度。eATP含量过高或者过低都会导致细胞死亡, 适度水平的eATP则有助于植物的生长和发育。细胞外三磷酸腺苷双磷酸酶(Apyrase)严格控制细胞外基质中eATP的水平, 因此有助于调控植物在逆境条件下的生长和防御反应。该文总结了植物中eATP的发现、产生和清除以及受体和信号转导等研究进展, 重点论述eATP在逆境条件下的生理功能, 并对植物eATP的研究方向作了展望。     

非生物逆境胁迫下植物钙信号转导的分子机制

Ca^2＋作为植物细胞中最重要的第二信使,参与植物对许多逆境信号的转导。在非生物逆境条件下,植物细胞质内的钙离子在时间、空间及浓度上会出现特异性变化,即诱发产生钙信号。钙信号再通过其下游的钙结合蛋白进行感受和转导,进而在细胞内引起一系列的生物化学反应以适应或抵制各种逆境胁迫。目前在植物细胞中发现Ca^2＋／CDPK、Ca^2＋／CaM和Ca^2＋／CBL3类钙信号系统,研究表明它们与非生物逆境胁迫信号转导密切相关。本文通过从植物在非生物逆境条件下钙信号的感受、转导到产生适应性和抗性等方面,介绍钙信号转导分子机制的一些研究进展。     

非生物逆境胁迫下植物钙信号转导的分子机制

Ca2+作为植物细胞中最重要的第二信使, 参与植物对许多逆境信号的转导。在非生物逆境条件下, 植物细胞质内的钙离子在时间、空间及浓度上会出现特异性变化, 即诱发产生钙信号。钙信号再通过其下游的钙结合蛋白进行感受和转导, 进而在细胞内引起一系列的生物化学反应以适应或抵制各种逆境胁迫。目前在植物细胞中发现Ca2+/CDPK、Ca2+/CaM和Ca2+/CBL 3类钙信号系统, 研究表明它们与非生物逆境胁迫信号转导密切相关。本文通过从植物在非生物逆境条件下钙信号的感受、转导到产生适应性和抗性等方面, 介绍钙信号转导分子机制的一些研究进展。     

逆境胁迫下植物体内活性氧代谢及调控机理研究进展

活性氧(reactive oxygen species, ROS)在植物生长发育中扮演着十分重要的角色。适当浓度的ROS是植物所必需的,而在逆境胁迫下ROS会大量积累,从而抑制植物的生长发育甚至杀死植物。为了维持体内ROS的动态平衡,植物进化出了一系列的ROS产生及清除机制。本文对近年来植物在逆境下的ROS产生、清除及其调节机制的研究进展予以综述,重点介绍转录及翻译后水平的ROS清除及其调节机制,并对植物ROS代谢及调控机理的研究提出了进一步展望。     

Immunomodulation of function of small heat shock proteins prevents their assembly into heat stress granules and results in cell death at sublethal temperatures

The conformational dynamism and aggregate state of small heat shock proteins (sHSPs) may be crucial for their functions in thermoprotection of plant cells from the detrimental effects of heat stress. Ectopic expression of single chain fragment variable (scFv) antibodies against cytosolic sHSPs was used as new tool to generate sHSP loss-of-function mutants by antibody-mediated prevention of the sHSP assembly in vivo . Anti-sHSP scFv antibodies transiently expressed in heat-stressed tobacco protoplasts were not only able to recognize the endogenous sHSPs but also prevented their assembly into heat stress granula (HSGs). Constitutive expression of the same scFv antibodies in transgenic plants did not alter their phenotype at normal growth temperatures, but their leaves turned yellow and died after prolonged stress at sublethal temperatures. Structural analysis revealed a regular cytosolic distribution of stress-induced sHSPs in mesophyll cells of stress-treated transgenic plants, whereas extensive formation of HSGs was observed in control cells. After prolonged stress at sublethal temperatures, mesophyll cells of transgenic plants suffered destruction of all cellular membranes and finally underwent cell death. In contrast, mesophyll cells of the stressed controls showed HSG disintegration accompanied by appearance of polysomes, dictyosomes and rough endoplasmic reticulum indicating normalization of cell functions. Apparently, the ability of sHSPs to assemble into HSGs as well as the HSG disintegration is a prerequisite for survival of plant cells under continuous stress conditions at sublethal temperatures.     

The small heat shock proteins in plants are members of an ancient family of heat induced proteins

In response to high temperature stress, plants express numerous small heat shock proteins (sHSPs) belonging to at least five related gene families. in vitro studies suggest sHSPs act as molecular chaperones to prevent irreversible heat denaturation of other proteins. The diversity of sHSPs in plants is unique among eukaryotes and makes it of interest to understand the origins of these proteins. sHSP-related proteins have now been identified in 13 prokaryotes, and in many of these prokaryotes the sHSPs are heat-regulated as seen higher plants. The prokaryotic sHSPs were analyzed by pairwise and mutliple sequence alignments with each other and with plant sHSPs. The higher plant class I cytosolic sHSPs are shown to be most similar to a subset of the prokaryotic sHSPs, including HSP 16.6 from the cyanobacterium Synechocystis. Genetic studies in this model cyanobacterium may provide insight into sHSP function in vivo, and into potential roles of sHSPs in higher plant cells.     

Analysis of Chaperone Function and Formation of Hetero-oligomeric Complexes of Hsp18.1 and Hsp17.7, Representing Two Different Cytoplasmic sHSP Classes in Pisum sativum

Small heat shock proteins (sHSPs) are the most abundant stress proteins in plants. Usually not expressed under permissive conditions, they can accumulate to more than 2% of the total cellular protein content during heat stress. At present several points of evidence indicate that these proteins act as molecular chaperones by keeping partially denatured proteins in a folding-competent state. In plants sHSPs are encoded by a multigene family, which can be segregated into several classes according to their subcellular position and/or sequence homology. Curiously, two different classes appear in the cytoplasm. Their specific role during heat shock remains elusive. Here we present some evidence that both classes of sHSPs enhance recovery of reporter protein activity in the presence of HSP70. Applying peptide arrays prepared by SPOT synthesis and in situ analysis by confocal laser scanning microscopy, we could further show that the two classes of sHSP are attached to each other and are able to interact with non-native proteins both in vivo and in vitro. Although both of the sHSPs act similarly as molecular chaperones, immunohistochemistry experiments support the hypothesis that the two have different cellular functions in the development of heat-induced cytoplasmic heat shock granules under elevated temperatures. Daniela Wagner Deceased 24 Feburary 2004.     

A cytosolic class I small heat shock protein, RcHSP17.8, of Rosa chinensis confers resistance to a variety of stresses to Escherichia coli, yeast and Arabidopsis thaliana

Among the heat shock proteins (HSPs) of higher plants, those belonging to the small HSP (sHSP) family remain the least characterized in functional terms. To improve our understanding of sHSPs, we have characterized RcHSP17.8 from Rosa chinensis . Sequence alignments and phylogenetic analysis reveal this to be a cytosolic class I sHSP. RcHSP17.8 expression in R. chinensis was induced by heat, cold, salt, drought, osmotic and oxidative stresses. Recombinant RcHSP17.8 was overexpressed in Escherichia coli and yeast to study its possible function under stress conditions. The recombinant E. coli and yeast cells that accumulated RcHSP17.8 showed improved viability under thermal, salt and oxidative stress conditions compared with control cultures. We also produced transgenic Arabidopsis thaliana that constitutively expressed RcHSP17.8. These plants exhibited increased tolerance to heat, salt, osmotic and drought stresses. These results suggest that R. chinensis cytosolic class I sHSP (RcHSP17.8) has the ability to confer stress resistance not only to E. coli and yeast but also to plants grown under a wide variety of unfavorable environmental conditions.     

Analysis and Phylogeny of Small Heat Shock Proteins from Marine Viruses and Their Cyanobacteria Host

Small heat shock proteins (sHSPs) are oligomeric stress proteins characterized by an α-crystallin domain (ACD) surrounded by a N-terminal arm and C-terminal extension. Publications on sHSPs have reported that they exist in prokaryotes and eukaryotes but, to our knowledge, not in viruses. Here we show that sHSPs are present in some cyanophages that infect the marine unicellular cyanobacteria, Synechococcus and Prochlorococcus. These phage sHSPs contain a conserved ACD flanked by a relatively conserved N-terminal arm and a short C-terminal extension with or without the conserved C-terminal anchoring module (CAM) L-X-I/V, suggested to be implicated in the oligomerization. In addition, cyanophage sHSPs have the signature pattern, P-P-[YF]-N-[ILV]-[IV]-x(9)-[EQ], in the predicted β2 and β3 strands of the ACD. Phylogenetically, cyanophage sHSPs form a monophyletic clade closer to bacterial class A sHSPs than to cyanobacterial sHSPs. Furthermore, three sHSPs from their cellular host, Synechococcus, are phylogenetically close to plants sHSPs. Implications of evolutionary relationships between the sHSPs of cyanophages, bacterial class A, cyanobacteria, and plants are discussed.     

Over-Expression of <Emphasis Type="Italic">PmHSP17.9</Emphasis> in Transgenic <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis> Confers Thermotolerance

Small heat shock proteins (sHSPs) have been shown to be involved in stress tolerance. However, their functions in Prunus mume under heat treatment are poorly characterized. To improve our understanding of sHSPs, we cloned a sHSP gene, PmHSP17.9, from P. mume. Sequence alignment and phylogenetic analysis indicated that PmHSP17.9 was a member of plant cytosolic class III sHSPs. Besides heat stress, PmHSP17.9 was also upregulated by salt, dehydration, oxidative stresses and ABA treatment. Leaves of transgenic Arabidopsis thaliana that ectopically express PmHSP17.9 accumulated less O₂ ^? and H₂O₂ compared with wild type (WT) after 42 °C treatment for 6 h. Over-expression of PmHSP17.9 in transgenic Arabidopsis enhanced seedling thermotolerance by decreased relative electrolyte leakage and MDA content under heat stress treatment when compared to WT plants. In addition, the induced expression of HSP101, HSFA2, and delta 1-pyrroline-5-carboxylate synthase (P5CS) under heat stress was more pronounced in transgenic plants than in WT plants. These results support the positive role of PmHSP17.9 in response to heat stress treatment.     

Comparative analysis of the small heat shock proteins in three angiosperm genomes identifies new subfamilies and reveals diverse evolutionary patterns

The small heat shock proteins (sHSPs) are a diverse family of molecular chaperones. It is well established that these proteins are crucial components of the plant heat shock response. They also have important roles in other stress responses and in normal development. We have conducted a comparative sequence analysis of the sHSPs in three complete angiosperms genomes: Arabidopsis thaliana, Populus trichocarpa, and Oryza sativa. Our phylogenetic analysis has identified four additional plant sHSP subfamilies and thus has increased the number of plant sHSP subfamilies from 7 to 11. We have also identified a number of novel sHSP genes in each genome that lack close homologs in other genomes. Using publicly available gene expression data and predicted secondary structures, we have determined that the sHSPs in plants are far more diverse in sequence, expression profile, and in structure than had been previously known. Some of the newly identified subfamilies are not stress regulated, may not posses the highly conserved large oligomer structure, and may not even function as molecular chaperones. We found no consistent evolutionary patterns across the three species studied. For example, gene conversion was found among the sHSPs in O. sativa but not in A. thaliana or P. trichocarpa. Among the three species, P. trichocarpa had the most sHSPs. This was due to an expansion of the cytosolic I sHSPs that was not seen in the other two species. Our analysis indicates that the sHSPs are a dynamic protein family in angiosperms with unexpected levels of diversity. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.